Extending optical lithography with immersion

OPC tools are already equipped with the most advanced models for image formation, capable of thin-film modeling, vector diffraction modeling and polarization modeling. Accurate simulation of immersion lithography, even in the context of OPC, does not pose any particular difficulty. In this paper we use the optical simulator of Calibre to study source polarization and its impact in process latitude and in proximity and linearity curves. More than 10nm difference in both curves is observed vs. source polarization at an immersion NA>1, projected to print the 45nm node. Simulation of large and arbitrary layout snippets confirm these results and demonstrate the feasibility of using advanced models in the context of OPC. Also, dry and water-immersion lithography are compared at the same NA<1 and the main differences in imaging are highlighted. The depth-of-focus increase in immersion is confirmed both in the ambient medium and also in the available DOF in resist. The DOF simulation results correlate closely with recent experimental work from other researchers.

show abstract

“…From these plots a ~1.6-1.7X improvement in available DOF is evident. These simulations confirm experimental results recently presented in [10]. …”

Section: Ambient: Air (N=1)supporting

confidence: 94%

Polarization effects in immersion lithography

Adam

Maurer

2004

SPIE Proceedings

View full text Add to dashboard Cite

show abstract

“…[ 3 ] Fabrication of composite materials with designed constituent elements of sub-micrometer size typically requires cutting edge lithography techniques such as immersion lithography, [ 4 ] nanoimprint lithography, [ 5 ] or e-beam lithography. [ 6 ] While these techniques are capable of printing features with the requisite lateral dimensions, they are all planar patterning approaches, and hence offer limited options for creation of 3D structures, or structures with out-of-plane components.…”

Section: Fabrication Of 3d Metamaterials Resonators Using Self-alignedmentioning

confidence: 99%

Fabrication of 3D Metamaterial Resonators Using Self‐Aligned Membrane Projection Lithography

et al. 2010

View full text Add to dashboard Cite

show abstract

“…As a result, topography effects have a significant influence on the diffraction properties of reticles 1 . This will become even more severe with the emergence of immersion lithography extending imaging to the sub-50nm regime [2][3][4][5][6] . The intensity distribution of the diffracted light is substantially different from the case of an infinitely thin mask, which is often referred to as the Kirchhoff-approximation.…”

Section: Introductionmentioning

confidence: 98%

Investigation of polarization effects on new mask materials

Bubke

Teuber

Hoellein

et al. 2005

Optical Microlithography XVIII

View full text Add to dashboard Cite

As microlithography moves to smaller critical dimensions, structures on reticles reach feature sizes comparable to the operating wavelength. Furthermore, with increasing NA the angle of incidence of light illuminating the mask steadily increases. In particular for immersion lithography this will have severe consequences on the printing behavior of reticles. Polarization effects arise which have an impact on, among other things, the contrast of the printed image. Angular effects have to be considered when aggressive off-axis illumination schemes are used. Whereas numerous articles have been published on those effects and the underlying theory seems to be understood, there is a strong need for experimental verification of properties of real masks at the actinic wavelength. This paper presents measurements of polarization effects on different mask blank types produced at Schott Lithotec including chrome and alternative absorber binary mask blanks, as well as phase shift mask blanks. Thickness and optical dispersion of all layers were determined using grazing incidence x-ray reflectometry (GIXR) and variable angle spectroscopic ellipsometry (VASE). The set of mask blanks was patterned using a special design developed at the Advanced Mask Technology Center (AMTC) to allow measurements at different line width and pitch sizes. VUV Ellipsometry was then used to measure the properties of the structured materials, in particular the intensities in the 0 th and 1 st diffraction order for both polarization directions and varying angle of incidence. The degree of polarization of respective mask types is evaluated for dense lines with varying pitches and duty cycles. The results obtained experimentally are compared with simulations based on rigorous coupled wave analysis (RCWA).

show abstract

Extending optical lithography with immersion

Cited by 32 publications

References 2 publications

Polarization effects in immersion lithography

Polarization effects in immersion lithography

Fabrication of 3D Metamaterial Resonators Using Self‐Aligned Membrane Projection Lithography

Investigation of polarization effects on new mask materials

Contact Info

Product

Resources

About